The most naive solution would be to simply do both evalutations independently:

```
catMaybesCount :: [Maybe a] -> ([a], Int)
catMaybesCount xs = (catMaybes xs, length $ filter isNothing xs)
```

I don't know if GHC is able to optimize this properly, but the `length . filter p`

solution for counting `Nothings`

has some peculiarities anyway (see this SO post for an overview).

Theoretically, this solution could require two passes over the list, instead of the one

This is a recursive solution solving this issue I came up with:

```
import Data.Maybe
-- | Equivalent to @catMaybes@, but additonally counts @Nothing@ values
catMaybesCount :: [Maybe a] -> ([a], Int)
catMaybesCount xs = catMaybesCountWorker xs [] 0
-- | Worker function for @catMaybesCount@
catMaybesCountWorker :: [Maybe a] -> [a] -> Int -> ([a], Int)
catMaybesCountWorker [] justs cnt = (justs, cnt)
catMaybesCountWorker (Nothing:xs) justs cnt =
catMaybesCountWorker xs justs (cnt + 1)
catMaybesCountWorker ((Just v):xs) justs cnt =
catMaybesCountWorker xs (justs ++ [v]) cnt
```

As applying it to a list should evaluate the list only once, this should be more efficient.

However I am worried about the `justs ++ [v]`

anti-idiom, as `(:)`

would be more efficient (see this discussion). However, this would invert the resulting list. Maybe someone with more knowledge on this topic could have a look at it?

Note that this function won't terminate for infinite lists because the `Nothing`

count will never finish to evaluate.